Run resistant knitted stockings



Nov. 17, 1964 M. B. NEBEL ET AL Original Filed Aug. 17, 1962 6 Sheets-Sheet 1 FZ'C'F: 2

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Nov. 17, 1964 M. B. NEBEL ETAL 3,157,037

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United States Patent r 3,157,037 RUN RESHSTANT KNITTED STOCKINGS Max Bruno N ebel, Waidstrasse 160, and Erhard M. N ebel, Heienenstrasse 28, both of Wiesbaden, Germany Original application Aug. 17, 1962, Ser. No. 217,554.

Divided and this application Nov. 19, 1962, Ser. No.

Claims priority, application Germany Feb. 18, 1961 6 Claims. (Ci. 66-178) This invention relates to run-resistant or ladder resistant fabrics, and more particularly relates to improvements in circular-knit run-resistant fabrics for stockings and in methods and apparatus for producing the same.

This application is a division of our earlier filed patent application Serial No. 217,554, filed August 17, 1962, which in turn was a continuation-in-part of our still earlier filed patent application Serial No. 173,419, filed February 15, 1962, now abandoned.

A principal object of this invention is to provide a highly run-resistant fabric having an attractive appearance in which the loop formation increases the stitch security and the walewise extensibility of the fabric.

Another object is to provide a circular-knit ladys stocking made wholly or partially of such run-resistant fabric.

Other objects of the invention will become apparent when the following description is read with reference to the accompanying drawings, in which:

FIG. 1 is a fragmentary, schematic view of a runresistant fabric made in accordance with this invention, the same being stretched walewise.

FIG. la shows the fabric of FIG. 1 unstretched.

FIG. 2 is a view in side elevation of a ladys circular knit stocking made in accordance with this invention.

FIGS. 3-9 are fragmentary views in side elevation showing different forms of sinkers constructed in accordance with this invention.

FIG. is a fragmentary view in top plan showing sinkers of the type illustrated in FIGS. 3 and 4 with a portion of the sinker nebs broken away.

FIG. 11 is a fragmentary view of a conventional sinker.

FIG. 12 is a fragmentary, schematic development in elevation illustrating one preferred arrangement of knitting cams, in accordance with this invention, in a circular knitting machine.

FIG. 13 is a fragmentary, vertical section taken at a yarn feed of a circular knitting machine showing one preferred arrangement for automatically changing the stitch draw level of the needles by movement of the knitting cams.

FIGS. 14 and 15 are fragmentary, vertical sections taken at different yarn feeds of a multi-feed circular knitting machine.

FIG. 16 is a fragmentary, schematic view of a modified inn-resistant fabric made in accordance with this invention, the same being stretched walewise.

FIG. 16a shows the fabric of FIG. 16 unstretched.

FIGS. 17 and 18 are fragmentary, schematic views of still other modified forms of run-resistant fabric made in accordance with this invention.

The terms stitch and knitted stitch as used throughout the specification and claims hereof shall indicate a loop of yarn which has been pulled through a preceding loop of yarn.

The term casting off shall indicate the discharge of a loop of yarn from a needle as a newly formed loop of yarn is pulled through the discharged loop to form a stitch.

The term unknitted stitch shall indicate a stitch which has been pulled out of its original loop formation and has receded completely, or nearly completely, into a previous stitch or yarn loop. An unknitted stitch may have a slight loop formation, depending upon the amount of yarn drawn or robbed from it.

The term stitch draw level shall indicate the lowest level to which a needle descends in casting off a stitch or yarn loop.

The term clearing level shall indicate the level to which a needle rises to clear yarn from its latch.

The term tuck level shall indicate the level to which a needle rises to take yarn while retaining a loop of yarn on its latch.

The terms thread and yarn are used as synonyms throughout the specification and claims hereof.

FIG. 1 shows a run-resistant fabric constructed in accordance with this invention stretched lengthwise (i.e. walewise) in such a way that all the knitted stitches are in loop formation to some extent. This fabric consists of courses b alternating with courses a. In the courses b the thread length per course preferably does not exceed of the thread length per course in the courses a. A course b consists of elongated stitches B alternating with short locking stitches S, while a course a consists of stitches A alternating with tuck loops F. The tuck loops F have substantially the same length x as the stitches A, and are doubled with stitches B throughout the fabric.

It will be seen that the short locking stitches S are anchored by the stitches A throughout the fabric. A locking of the stitches A in the fabric structure is achieved by forming the stitches A in alternate wales of the courses a and by extending the intervening stitches B of the preceding courses b over two courses, obtaining the necessary supply of yarn to thus elongate stitches B from the neighboring stitches S. As a result, the stitches S are contracted to such an extent as to form short stitches which lock the stitches A.

The forming of courses a and b with different lengths of yarn per course, and the forming of the small stitches S, create a stress relationship on the yarn loops such that the needle stitches are hindered from running and forming ladders during wear. This loop structure, when made from fine threads, gives the knitted fabric a fine, net-like appearance.

The length of the thread per course in the courses b in relation to the thread lengths of the courses a must not be so great as to prevent the fabric from having the desired run-resistant property, and must not be so small as to lead to overtensioning or breaking of the thread during knitting. Basically, the thread lengths of courses b must be short enough relative to the thread lengths of courses a so that courses b take all the strain that can be placed on the fabric in any direction, i.e., courses a must be so loose that the threads making up these courses are never tensioned sufiiciently to pull stitches A back through stitches S, if a thread is broken, irrespective of how the fabric is pulled. The greater the tension on the fabric, the more the locking stitches S of the courses b are pulled tight, in consequence of which ladders or runs for all practical purposes are prevented. In order to achieve this desideratum, it has been found in practice that the length of yarn per course of the courses b preferably should be from 45% to 70% of the length of yarn per course of the courses a.

By using a mesh pattern with one needle step in knitting from courses a to courses b, every needle Wale contains, sequentially, stitches A, elongated stitches B, tuck loops F and locking stitches S. As a result, in the fabric of FIG. 1, the stitches A and tuck loops F of each course a are staggered, i.e., offset walewise, with respect to the stitches A and tuck loops F of the next adjacent courses a. Similarly, the stitches B and S of the courses b are staggered with respect to the stitches B and S of the next adjacent courses b.

It may be found advantageous to knit an additional reinforcement thread with the courses b and/or with the courses a.

In FIG. la, the fabric of FIG. 1 is shown unstretched, with the result that the short stitches S become unknitted. The extent to which the stitches S become unknitted and recede back into the previous stitches in a wale depends upon the ratio of the thread lengths of the courses a to the thread lengths of the courses 1).

Referring to the exemplary ladys stocking shown in FIG. 2, the leg portion 10, the sole portion 12 and the instep portion 14 of the stocking may be made of runresistant fabric according to the invention, while the heel portion 16 and the toe portion 18 may be of conventional fabric. The welt 20 and the shadow welt 22 also may be of conventional fabric, knitted with a heavier thread, if desired. The circumference of the stocking may vary in size. For example, the upper portion of the leg from the area of numeral 24 to the knee area 26 may be knitted to include relatively large yarn loops to form a relatively large circumference, and the portion from the knee area 26 to the middle of the calf 28, or down to the ankle 29, may be knitted with gradually smaller loops to form a circumference of progressively decreasing size. From there on the loops and circumference may remain of the same size through the foot portion 12, 14 to the toe 18.

A further construction is one in which the toe portion 18 also consists of run-resistant fabric in tubular form, shaped by cutting off the surplus fabric and seaming.

A further construction is one in which the heel portion 16 is tubular knitted of run-resistant fabric and boarded to shape. The fabric of the heel portion 16 may be knitted with an additional thread as reinforcement, and, if desired, this reinforcement may be extended into the sole portion 12.

Production of the run-resistant fabric of FIGS. 1, 1a involves, first, forming on a set of needles a course b initially of substantially equal size yarn loops which are to form the short unknitted stitches S and the elongated stitches B. Then there is formed on the needles a course a of stitches A and tuck loops F, all of greater loop length than the loops of the first course b. As course a is formed, the loops of the course b are cast off from those needles which form the stitches A, while the loops of the course b are retained on the needles which form the tuck loops F and are enlarged to form the elongated stitches B by robbing or drawing thread from the cast-off stitches, thereby contracting said cast-off stitches to form them into the small locking or unknitted stitches S.

The result of this method is that the loops of the course b which remain on the needles are pulled down, during the sinking of the course a, with the tuck loops F, and therefore are drawn to approximately the same loop length as loops F and A to form the elongated stitches B at the expense of the stitches S.

For practicing the method of the invention on a circular machine, sinkers may be used which have yarn sinking points at two different heights, either both behind a sinker neb or hook or one in front of and the other behind the sinker neb.

It is highly advantageous to achieve this method of operation with the aid of sinkers P (FIGS. 3 and 4), which have behind their nebs ph differential yarn sinking ledges pa, pt joined by an inclined edge pc, and before their nebs ph a yarn sinking ledge pd at the same height as the ledge pt. Preferably, the sinking ledges pa and pt have a difference in height corresponding to the difference between the loop lengths of the courses a and courses b as initially formed.

Other forms of sinkers are useful too. FIG. shows another preferred sinker P1 having only one yarn sinking ledge pa behind its neb ph, which sinking ledge is higher than the sinking ledge pd before the sinker neb. FIG. 6 shows a sinker P3 with a yarn sinking ledge pb behind the sinker neb plz at the same height as the ledge pd before the neb. The sinker ledge pd terminates in a notch px, next to the neb ph. FIG. 7 shows a sinker P4 with a yarn sinking ledge pk behind the sinker hook ph, lower than the sinking ledge pd before the sinker hook. FIG. 8 shows a sinker P5 which is similar to sinker P1 (FIG. 5), except for the presence of the notch px. FIG. 9 shows a sinker P2 which is similar to the sinker P, except that the sinking ledge pt is lower than the ledge pd.

FIGS. 3 and 10 show the completion of the sinking of the loops of the thread of a course a, with the sinkers P. Needle N in FIG. 3 is at stitch draw level. This course a is formed, by the needles, behind the sinker nebs ph on the sinking points pa (which lie higher than the sinking points pd, pt) into tuck loops F and stitches A in alternation. Stitches B of a course b, which had remained on the latches of the alternate needles that produce the tuck loops F, lie in front of the sinker nebs ph on the lower sinking points pd and are pulled down by the needles a distance less than that of stitches A and tuck loops F because of the difference in height of ledges or sinking points pa and pd. Since the needles sink the loops of course a behind the sinker nebs ph, and the stitches B of course b extend from the sinker throats to the needles, it is apparent, from FIG. 3, that as tuck loops F are formed, stitches B are enlarged to approximately the same loop length as tuck loops F, since the needles pull stitches B slightly rearwardly of the sinker throats. With the method shown in FIG. 3, strain or tension on the loops B is reduced during sinking of the tuck loops F.

FIG. 4 shows the completion of the sinking of a loop S of a course b, with the sinkers P. Needle N in FIG. 4 also is at stitch draw level, casting off simultaneously a stitch B and a tuck loop F. The loops of course b are formed into the alternate stitches B and S behind the sinker nebs plz on the sinking points or ledges pt. Stitches B and S initially are formed of the same size by the sinking of the yarn of course b on the sinking ledges pt.

Thus, from FIGS. 3, 4 and 10, it is clear that the stitches B and S of a course b initially are of the same size, and when the stitches B are pulled downwardly a second time, on the sinking ledges pd, during formation of the tuck loops F of a course a, they (stitches B) are enlarged by drawing yarn from the intervening stitches S which are cast off during formation of the course a. The needle action is similar to that shown in FIGS. 13- 18. In FIG. 10, stitches S actually are unknitted, but have been shown in slightly exaggerated loop formation for the purposes of clarity.

For producing the loops of a course a with sinkers P, the sinkers, by well known cam means, are moved forward between the needles N to bring their yarn sinking ledges pa under the yarn feed for that course. Similarly, for producing the loops of a course b, the sinkers P are advanced slightly further into the needle circle to permit sinking of yarn on the ledges pt. Before formation of the next successive course a, however, the sinkers P are retracted outwardly by well known cam means to transfer the loops of the newly formed courses a and b from the sinking ledges behind the sinker nebs to the sinking ledges pd in front of the sinker nebs. Immediately thereafter, sinkers P again are advanced into the needle circle to permit formation of the loops of a new course a on the yarn sinking ledges pa.

With respect to sinkers P, the difference in height between the sinking ledges pa on the one hand and ledges pd and pt on the other hand may be in direct proportion to the desired difference in yarn length per course of the courses a and b. For example, if it is desired that a fabric be knitted wherein, at least in the initial courses, the ratio of the length of yarn in a course a to the length of yarn in a course b is 2:1, i.e., the length of yarn in a course b is 50% of the length of yarn in a course a, then the height of sinking ledge pa, in comparison to the height of the sinking ledges pd and pt, may be such as to form a yarn loop on sinking ledge pa which would be twice the length of a yarn loop formed on the sinking ledges pd or pt. This assumes, of course, that the stitch draw levels for courses a and b are the same during formation of the said initial courses. I

In view of the novel method of fashioning circular knitted fabric, to be described hereinafter, wherein plural stitch cams are adjustable independently relative to a needle cylinder and to each other, the ratios of the yarn lengths in courses a and b may be selectively varied with any given set of sinkers by'appropriate control and adjustment of the stitch cam positions.

- FIG. 5 shows a method of producing a course b of the fabric of FIGS. 1, 1a, with sinkers P1. The usual sinker ledge pd lies before the sinker neb ph at the usual level,

.and is the sinking point for the loops for stitches S, B

of a course b. The higher ledge pa behind the neb ph provides the sinking point for the yarn loops of a course a. The needle N inFIG. 5 also is at stitch draw level, and is shown casting off a tuck loop F and a stitch B.

The motion of the sinkers P1 is such that during the production of a course b on ledges pd the sinkers are actuated in the usual way in relation to the needles, and for the production of a course a the sinkers P1 are advanced into the needle circle to enable the needles to sink yarn on the ledges pa behind the nebs ph. The

needle action, of course, connected with the use of sinkers P1, is similar to that shown in FIGS. 13-18.

Referring now to FIG. 9, the sinker P2 has behind its neb ph sinking ledges pt and pa, which are connected by the inclined edge pc, and, in contrast with sinker P (FIG. 3), the sinking ledge pd is located at a level which lies intermediate of the level of the sinking ledges pt and pn.

With the sinker P2, a somewhat better casting off of the stitches A of a course a can be obtained because the sinking ledgept for courses b lies a little lower than the sinking ledge pd. Thus, the needles, during the production of a course b, can be drawn lower than during the production of a course a without forming loops of too large a size. By this method the stitches B will be less strained when drawn down the second time, and may easily draw their additionally required thread length from the cast off stitches S. During this second sinking motion, the stitches B are elongated to a size which substantially corresponds to the size of the loops of course a, and the stitches S are contracted in the manner shown in FIG. 10.

Referring to FIG. 7, sinker P4 may be used with a sinking point pk, behind the hook ph, which lies lower than the usual sinking point pd in front of the hook ph. With this sinker, the thread for courses a is formed in front of the neb on sinking point pd and the thread for courses b is pulled on the lower-lying sinking point pk by means of the needles.

According to a further embodiment of this invention, instead of using sinkers with yarn sinking points at two different heights in a circular knitting machine with two or more yarn feeds, the fabric of FIGS. 1, la may be knit with the conventional sinkers P6 shown in FIG. 11., by positioning the knitting cams so that the stitch cam at the feed for forming courses b is adjusted higher,

in the direction of needle motion, than the stitch cam at the feed for forming courses a, as shown in FIG. 12. In such method ofthe invention, either or both of the coplanar yarn sinking ledges pd, pb of sinker P6 may be utilized for sinking the yarn.

This further method of the invention is illustrated and described in our earlier filed patent application aforesaid, Serial No. 217,554, of which this application is a division. FIG. 12 shows schematically one preferred setting of the knitting cams for forming the fabric of FIGS. 1, la. Yarn for the short yarn courses b is fed to the needles N at yarn feedin station I having a stitch earn 100, a top center cam 101, a landing earn 102 and a rise cam 163. Yarn for the long yarn courses a is fed at yarn feeding station II which includes stitch earn 105, top center earn 166, landing cam 107 and a rise cam 108.

Stitch cam is positioned to draw the needles down to a lower level than that to which they are drawn by stitch cam 100. The difference in drawing depth of the two stitch cams 105, 1th) is indicated at R. Thus, stitch cam 105 will draw the needles downwardly to form a course of longer loops and greater yarn length than that of a course formed at yarn feeding station I. Of course, if desired, the arrangement of FIG. 12 may be reversed so that the long yarn courses are formed at station I and the short yarn courses are formed at station II.

In knitting ladies hosiery on circular machines, it is standard practice to shape or fashion the stocking to improve the fit on a wearers leg by progressively reducing the circumference of the tubular leg portion 10 (FIG. 2) between the knee and the ankle. Such reduction in the stocking circumference is accomplished by reducing the size of the stitches as knitting proceeds toward the ankle. In the typical stocking shown in FIG. 2, the reduction of stitch size usually takes place between the areas indicated by numerals 26 and 29.

In most circular machines used in knitting ladies hosiery, reduction of stitch size for shaping of a stocking is accomplished by gradually lowering the needle cylinder relative to the'knitting cams. In some machines, however, the knitting cams are raised relative to the needle cylinder. Regardless of which technique is employed, the result is to bring the sinkers and knitting cams relatively closer together with consequent reduction of the yarn draw of the needles, thus resulting in a shortening of the lengths of the stitches which are knitted.

In this invention, when passing from a part of a fabric 1% (FIGS. 1, 1a, 2) having one circumference to apart having a smaller circumference, and while reducing the size, i.e., length x of the stitches A and tuck loops F in the direction of knitting of the stocking from the welt to the foot, it is advantageous that the stitches B be reduced in size (in their dimension x) in such manner that the small locking stitches S, in their contracted form, maintain a predetermined relative size.

With this invention, the size of the initial loops of the courses b may be progressively reduced at about one half of the rate of reduction in size of the loops of the courses a, so that the ratio between the thread lengths of the courses a and b remains substantially the same at all times.

However, if the courses b in the leg fabric area having the largest circumference have a thread length which is more than half the thread length in the courses a, then during the gradual reduction of the loop sizes for the smaller circumference portion of the stocking it is desirable that the thread length of the courses b be altered progressively to less than half of the thread length of the courses a. In the latter event, however, it is advantageous to make the change in the circumference of the fabric tube, i.e., in the loop sizes, to a lesser degree than normal, so that the increase in the ratio of the thread lengths is less effective in shaping the stocking. Final shaping o the stocking, of course, is obtained by boarding.

With some stocking constructions of this invention, however, it may be desirable to reduce progressively the difference in thread length between the courses a and b as shaping of the stocking progresses. Such method would be advantageous where the courses b initially have a thread length which is half or less than half the thread length of the courses a.

In connection with the knitting of a ladys stocking on a multi-feed machine incorporating the fabric of FIGS. 1, la, this invention provides for the knitting cams at one feed, at least, to be independently adjustable relative to the axis of the needle cylinder during its lowering to shape the fabric. Preferably, the knitting cams at the yarn feed where the yarn for the courses b is fed is independently movable in the direction of needlernotion during I axial movement of the needle cylinder. As a result, as the loops in the courses a are progressively reduced in size by axial movement of the needle cylinder relative to the knitting cams, the knitting cams for knitting courses b are adjusted automatically to independently control the size of the stitches of the courses b.

With such changes in the loop sizes of the stocking fabric and in the relative positions of the knitting cams axially of the needle cylinder, the motion of the sinkers may change in such a way that during the knitting of courses of increasingly smaller loops, the depth of movement of the sinkers through the needles for cast off becomes proportionately smaller.

The novel method of shaping or fashioning a circular knit stocking fabric in accordance with this invention, as referred to above, will now be described with particular reference to the method of knitting illustrated in FIG. 12, wherein the difference in thread length of the courses a and b is achieved by positioning the stitch cams 100, 105 to draw the needles at feeding stations I and II to different stitch draw levels. In FIG. 13 such a movable knitting cam arrangement with the essential cooperating devices is shown by way of example, for a yarn feed for courses [2. The knitting earns 36, 32 are movable towards the needle cylinder 34 independently when required, and also are movable upwardly and downwardly axially, or nearly axially, with respect to the needle cylinder. In FIG. 13, stitch cam 39 and its landing cam 32 are shown as being integral, but these cams may be separate, if desired.

The cams 30, 32 are attached to a slide 36 which is supported in a guide 38 and is displaceable by means of a lever 40 in a horizontal path towards the cylinder 34 so that the cams will act on the needle butts N1 to operate the needles. The cams are withdrawable to terminate operation of the needles. The guide 38 is pinned to the movable shaft 42 which, in turn, is held in a bearing 44 supported by a plate 46. Therefore, the cams 30, 32 can be moved up or down in the direction of travel of the needles N, i.e., in an almost vertical direction.

Spring 110 urges cams 30, 32 in a downward direction. A control cam 48 mounted on link 56 engages a roller 50 mounted on lever 52 which, in turn, is adjustably connected with the vertical lever 54. The lever 54 is connected to the movable shaft 42, so that by vertical movement of the control cam 48, the cams 30, 32 may rise or fall relative to the needle cylinder 34.

The link 56 is rigidly connected to a vertical lever 58 and is movable by means of other levers (not shown), which operate from the same cam which raises and lowers the needle cylinder 34 in the well known way. By means of the adjustable screw 60, the lever 54 is adjustable, and by means of the control cam 48 the knitting cams 3t 32 may be moved independently of the needle cylinder. By this construction, the ratio between the loop sizes and thread lengths of the courses b and a during changes in the loop sizes of the stockings, may be controlled as desired.

It is to be understood that the knitting cams at the yarn feed for forming the courses a may or may not be independently and automatically adjusted by the control means of FIG. 13 during knitting. If desired, the invention may be utilized to provide such knitting cam control means at all yarn feeds, whereby the stitch cams at all feeds may be selectively positioned as desired independent of any movement of the needle cylinder. In practice, however, at least one set of knitting cams, more conveniently those which form the courses a, preferably are stationary, whereby the loops formed with such cams are varied in size solely by movement of the needle cylinder.

In using the movable knitting cam construction of FIG. 13, in connection with producing courses b, the cams 30, 32 initially may be positioned at the same yarn drawing level as the knitting cams for the yarn feed producing 8 the courses a. Thus, the loops of yarn for the courses a and b will then be formed of equal size, with the method of FIG. 12. Such arrangement would be used, for example, in producing the plain knit welt 20 and afterwelt 22 of the stocking of FIG. 2. Upon commencing production of the leg portion 10 of the stocking, of the run-resistant fabric of FIGS. 1, 1a, the knitting cams 30, 32 automatically are elevated with respect to the knitting cams at the feed for courses a to a selected position to produce the courses In of a smaller loop size and thread length in the manner of the invention heretofore described. The leg portion 10 of the stocking then is knit with the knitting cams occupying such relative positions until the portion 28 of the fabric is reached, whereupon the needle cylinder 34 is lowered progressively to reduce the size of the loops which form the courses a. Simultaneously, the knitting cams 30, 32 are adjusted automatically relative to the needle cylinder 34, dependent upon the setting of the control mechanism of FIG. 13. to independently control the size of the loops of the courses I; as the needle cylinder is lowered. Thus, in the formation of the run-resistant fabric of FIGS. 1, la, the fabric is fashioned or shaped by controlling the positions of the knitting cams relative to the needle cylinder independently of each other, to thereby selectively control the size of the loops formed in the courses a and b.

If desired, sinkers P3 (FIG. 6) having yarn sinking notches px may be utilized in lieu of sinkers P6 (FIG. 11) when knitting the run-resistant fabric of this invention in accordance with the disclosures of FIGS. 12, 13. With such sinkers, the thread for the courses a is formed into loops on the sinker ledge pb behind the neb ph, while the thread for the courses [2 may be formed into loops on either ledge pb, or on ledge pd in front of the sinker neb. When the tuck loops F are formed, the stitches, B, which are within the needle hooks, are pulled downwardly into the notches px, and thereby are not unduly tensioned during the formation of a course a. In connection with the sinker P3, if normal or conventional courses of loops M are formed in the fabric, the sinking of these loops by the needles is done in front of the notch px on the sinking point pd (FIG. 6).

The method of shaping a tubular knit fabric illustrated in FIG. 13 is applicable, of course, to the method of knitting hereinbefore described in respect of sinkers having yarn sinking ledges at different heights (FIGS. 3-5, 7-10). Adaptations of this method of shaping the fabric are illustrated in FIGS. 14 and 15. FIG. 14 shows the knitting of the yarn for a long yarn course a with sinkers P1 at a yarn feed whereof the stitch cam 62 is fixed in position. In FIG. 15 there is illustrated the knitting of the yarn for a short yarn course b with sinkers P5 at a yarn feed having the movable knitting earns 30, 32 illustrated in FIG. 13.

FIG. 16 shows a modified form of the fabric of FIGS. 1, 1a in a stretched condition, and FIG. shows the same fabric unstretched. For convenience, the same reference letters are applied to the fabric of FIGS. 16, 16a as to the fabric of FIGS. 1, 1a except in respect of the tuck loops. The tuck loops of the fabric of FIGS. 16, 16a are in modified form, and are designated by the reference letter L.

Thus, in FIGS. 16, 16a short yarn courses 17 consist of short stitches S and long stitches B in alternation, while the long yarn courses a consist of modified tuck loops L and stitches A in alternation. Modified tuck loops L are not doubled with the elongated stitches B, but rather are pulled beyond those stitches and doubled with the small locking stitches S to form the double thread stitches S, D. When the fabric is relaxed and the short stitches S become unknitted and recede back into the stitches B, the bights of the modified tuck loops L recede with them in the manner shown in FIG. 16a.

The solid line fabric of FIG. 17 is another modified form of the fabric of FIGS. 1, 1a. For convenience, the

same reference letters are applied to corresponding identical parts of the two fabrics, which dilfer in the following respects: In FIG. 17, after a course a of stitches A and tuck loops F, there follows at least one course c of conventional stitches C. The thread length in the courses c may be the same as that of courses b, or it may be a little longer.

If the tuck loops F remain as conventional tuck loops, they are bound in between the stitches B and C, as shown in full lines in FIG. 17. However, the tuck loops F may be formed as modified tuck loops L and knitted in with the loops in the following course 0, in which event the double thread stitches C, D alternate in the course with the single thread stitches C, as shown by broken lines in FIG. 17.

The solid line fabric of FIG. 18 is still another modified form of the fabric in FIGS. 1, 1a. For convenience, the same reference letters are applied to corresponding identical parts of the two fabrics, which differ only in that the tuck loops F alternate with a diiferent frequency in the courses a. Thus, the solid line fabric of FIG. 18 varies from that of FIGS. 1, 1a in that the doubled tuck loops F and stitches B occur in every third Wale of a course a. By the same token, as indicated by the broken lines in FIG. 18, the doubled stitches S, D also may be staggered throughout the fabric of FIGS. 16, 16a in this manner. Of course, the mode and frequency of staggering the doubled tuck loops and stitches of the fabric is a matter of choice and may be carried out as desired throughout the fabric. It also will be understood that it is possible to insert in the fabric of FIG. 18, between courses a and b, one or more conventional courses c of plain loops in the manner shown in FIG. 17.

In any of the forms of the run-resistant fabric, the ratio of the thread length of a course a to that of a course b may be further increased by using a yarn with a higher rate of shrinkage for the course b and a yarn with a lower rate of shrinkage for the course a. On the other hand, a fully synthetic false twist, bulked, crimped or other textured yarn may be used for the course a and a fully synthetic yarn with normal shrinkage may be used for the course b, and it is possible to use fully synthetic yarn with normal shrinkage in the course a and a fully synthetic false twist, bulked, crimped or any other textured yarn for the course b.

Reference may be had to co-pending U.S. applications Serial No. 18,560, filed March 30, 1960, now Patent No. 3,080,740 and Serial No. 170,029, filed January 31, 1962, for the sinker and needle motions necessary for the production of the fabrics according to the embodiments of FIGS. 16, 16a, 17 and 18.

In the claims hereof, the term alternate is not intended to be restricted in meaning to indicate a 1 and 1 sequence, i.e., single spaced elements separated by other single elements, but may indicate any uniform sequence of spaced elements, such as 1 and 2, 1 and 3, 2 and 2, 2 and 1, etc.

The term tuck loop in the claims is used to indicate both tuck loops F as in FIG. 1 and modified tuck loops L as in FIG. 16.

Having thus described our invention, we claim:

1. In a circular knitted stocking having a welt and an ankle portion, a tubular leg portion disposed between the welt and ankle portion formed of run-resistant fabric incorporating:

(a) a plurality of selected courses wherein the yarn is formed into tuck loops in spaced wales and into knitted stitches in the intervening wales.

(b) courses immediately preceding the selected courses.

wherein the yarn is formed into relatively elongated stitches in thes paced wales and into relatively short stitches in the intervening wales.

(c) the length of yarn per course in said preceding courses being from 45 to 70% of the length of yarn per course in the selected courses, and

(d) at least part of said tubular leg portion having a progressively decreasing circumference in the direction from the welt to the ankle portion,

(e) the ratio of the length of yarn per course in the preceding courses to the length of yarn per course in the selected courses increasing with the decrease in the circumference of the tubular leg portion.

2. In a circular knitted stocking having a welt and an ankle portion, a tubular leg portion disposed between the welt and ankle portion formed of run-resistant fabric incorporating:

(a) a plurality of selected courses wherein the yarn is formed into tuck loops in spaced wales and into knitted stitches in the intervening wales,

(b) courses immediately preceding the selected courses wherein the yarn is formed into relatively elongated stitches in the spaced wales and into relatively short stitches in the intervening wales,

(c) the length of yarn per course in said preceding courses being from 45% to 70% of the length of yarn per course in the selected courses, and

(d) at least part of said tubular leg portion having a progressively decreasing circumference in the direction from the Welt to the ankle portion,

(e) the ratio of the length of yarn per course in the preceding courses to the length of yarn per course in the selected courses remaining substantially constant throughout said tubular leg portion.

3. A circular knit stocking having (a) a Welt formed of fabric having stitches of substantially uniform size and (b) a leg formed of a run-resistant fabric,

(c) said run-resistant fabric composed of (1) alternate courses wherein yarn is formed into tuck loops in spaced wales and into knitted stitches in the intervening wales and (2) courses immediately preceding the alternate courses wherein yarn is formed into relatively elongated knitted stitches in the spaced wales and into relatively short knitted stitches in the intervening wales,

(3) the length of yarn per course in said preceding courses being 70% or less of the length of yarn per course in the alternate courses.

4. The stocking of claim 3 wherein the run-resistant fabric incorporates at least one conventional course of plain stitches immediately successive to the alternate courses, the length of yarn per course in said conventional courses being at least as long as the length of yarn per course in the preceding courses.

5. The stocking of claim 4 wherein the tuck loops in the alternate courses are doubled with plain loops in the immediately succeeding conventional courses.

6. The stocking of claim 3 wherein the length of yarn per course in said preceding courses is from 45 to 70% of the length of yarn per course in the alternate courses.

References Cited in the file of this patent UNITED STATES PATENTS 1,123,924 Quinn Jan. 5, 1915 1,880,158 Siegel Sept. 27, 1932 1,890,299 Mutchler et al Dec. 6, 1932 2,022,157 Siegel Nov. 26, 1935 2,057,375 Friedmann Oct. 13, 1936 2,141,999 McNamee Dec. 27, 1938 2,190,409 Maier Feb. 13, 1940 2,609,677 Picard Sept. 9, 1952 FOREIGN PATENTS 548,017 Italy Sept. 8, 1956 

3. A CIRCULAR KNIT STOCKING HAVING (A) A WELT FORMED OF FABRIC HAVING STITCHES OF SUBSTANTIALLY UNIFORM SIZE AND (B) A LEG FORMED OF A RUN-RESISTANT FABRIC, (C) SAID RUN-RESISTANT FABRIC COMPOSED OF (1) ALTERNATE COURSES WHEREIN YARN IS FORMED INTO TUCK LOOPS IN SPACED WALES AND INTO KNITTED STITCHES IN THE INTERVENING WALES AND (2) COURSES IMMEDIATLELY PRECEDING THE ALTERNATE COURSES WHEREIN YARN IS FORMED INTO RELATIVELY ELONGATED KNITTED STITCHES IN THE SPACED WALES AND INTO RELATIVELY SHORT KNITTED STITCHES IN THE INTERVENING WALES, (3) THE LENGTH OF YARN PER COURSE IN SAID PRECEDING COURSES BEING 70% OR LESS OF THE LENGTH OF YARN PER COURSE IN THE ALTERNATE COURSES. 